Primer on Cryptoasset Valuations - Q4 2024

By 21Shares

Cryptoasset valuation remains an emerging topic seeking consensus, especially as the asset class expands and matures. Robert Greer, author of "What is an asset class anyway?" argues that assets that lack an objective measure of value and have a supply constraint are more vulnerable to irrational exuberance, citing the dot-com bubble as an example. Cryptoassets lack an objective measure of value today among investors, similar to emerging tech companies in the late 1990s. We propose valuation methodologies that reconcile various investors' approaches in recent years. 

We can value any asset using two approaches – intrinsic or relative. Intrinsic valuation measures an asset's value based on its capacity to generate cash flows. On the other hand, relative valuation methods, also called "pricing," estimate how much to pay for an asset based on what others are paying for comparable ones.

Investors might use a discounted cash flow method (DCF) to value a stock, but they wouldn't use that for a piece of fine art. Similarly, we must outline the various types of cryptoassets to understand the differences we may expect in their value accrual and specific valuation approaches. In this regard, it's zhelpful to categorize cryptoassets according to the three asset superclasses proposed by Robert Greer: 

1. Capital Assets: “An ongoing source of something of value” (e.g., bonds and stocks). 

2. Consumable/Transformable Assets: “You can consume it. You can transform it into another asset. It has economic value. But it does not yield an ongoing stream of value” (e.g., physical commodities).

3. Store of Value Assets: “They cannot be consumed, nor can they generate income. Yet they do have value” (e.g., currencies and collectibles).

Like the Internet architecture, cryptoassets and blockchain technology have two layers: (1) infrastructure and (2) applications. In his 2019 work, Chris Burniske categorized cryptoassets at the infrastructure layer based on the consensus mechanism of the blockchain:

1. Proof-of-Work (PoW): In PoW networks like Bitcoin, the native asset (BTC) relies on a computationally and energy-intensive lottery called mining to determine which block of transactions to settle on the blockchain and reward the miners. Hence, they belong to the Consumable/Transformable asset superclass, as they essentially create “a digital-native commodity in the form of secure, globally accessible ledger space.” Investors can use the mining cost of production as a fundamental metric to gauge the lower-bound price of PoW crypto assets like BTC. 

2. Proof-of-Stake (PoS): In networks like Ethereum and Solana, validators must commit a portion of their capital – the “stake,” in this case, ETH – to gain access to a recurring value stream generated by the network’s rules. Hence, they fall in the Capital Asset category, and their value may be derived from the net present value of annual flows to validators using a DCF method.

While we won’t delve too deeply into the application layer, we can apply the same first-principles thinking:

1. Governance tokens yield voting rights and represent ownership of the application. They are analogous to common stock in traditional finance, so they fall in the Capital Asset class. 

2. Utility tokens drive the economics of the system as their sole function, meaning they fall in the Consumable Asset category.

3. Non-fungible tokens (NFTs) are collectibles like fine art in their most typical form today, falling in the Store of Value category.

Figure 1: Asset Superclasses and Subsets

Source: 21Shares, ArkInvest

Intrinsic valuation

Ethereum

From the standpoint of a validator, PoS assets like ETH are akin to a stock paying a dividend yield, which means we can conduct a DCF valuation following four simple steps:

1. Estimate the cash flows during the life of the cryptoasset

• Transaction fees within the network accrue to validators. Just so, fees are a proxy for revenue. Ethereum validators received $483.28 million in transaction fees (net after the burn mechanism) from January 1, 2024, to December 31, 2024.

• Token issuance doesn’t dilute the value of validators. On the contrary, they have the right to new issuance, similar to how shareholders may receive stock-based compensation. ETH Issuance from January 1, 2024, to December 1, 2024, amounted to $2.88 billion.

• Total Cash Flows = Approximately $3.366 billion in the last year.

2. Estimate expected future cash flows and the lifespan of the crypto asset

• Future cash flows: We propose a slight variation of the three-stage growth model to project Ethereum’s future cash flows. Specifically, we forecast an initial period of aggressive growth, followed by an incremental decrease that eventually stabilizes at a more moderate growth rate.
  • Blob Space Fees: With the implementation of EIP-4844, revenue growth from blob fees should be factored into the model and projected forward. Since inception, blob fees have accounted for less than 1% of Ethereum’s yearly fees—a figure expected to rise as more users onboard via Layer 2s (L2s) as Ethereum’s scaling solution, as illustrated by the Ethereum scaling roadmap. By making Ethereum scalable, Layer 2s will onboard millions of users on-chain, further driving demand for blob space. As more L1s like Celo transition to L2s and Web2 and TradFi companies launch their own L2s, we project blob fee growth which we account for in the DCF.

• Lifespan of the asset: With public companies that at least in theory can last forever, equity analysts generally assume that cash flows beyond a specific point in time continue in perpetuity. Investors may apply the same logic to PoS cryptoassets, but for simplicity’s sake, we assume ETH’s life will be 20 years. 

3. Estimate the discount rate to apply to these cash flows

• Lower-bound discount rate (11.02%): Since inception, the Invesco QQQ Trust ETF obtained a 11.02% compound annual return

• Higher-bound discount rate (20.88%): Obtained using the Fama and French Three-Factor Model (market premium, size premium, and value premium).

4. Estimate the net present value (NPV) of cash flows using the above parameters

Assuming a discount rate of 11.02%, the implied price per one ETH today would be  around $10,427, a 213% increase from ETH’s price ($3,335) as of December 31, 2024. On the other hand, if we use a 20.88% discount rate, the implied price per one ETH would be $2,887, a 13% decrease from ETH’s current price. Investors should interpret the results of this DCF valuation with caution and run their own assumptions regarding projected cash flows and discount rates. The rationale behind our approach was to be conservative and capture the high volatility of ETH in the discount rate to accurately reflect the asset’s riskiness. Another implicit assumption of this approach is that the asset’s monetary premium is embedded into the DCF.

Figure 2: ETH DCF Valuation

Source: 21Shares. Data as of December 31, 2024

Bitcoin

When it comes to crypto-commodities, the marginal cost of production is vital as it sets the price floor at which producers (miners) are willing to sell. From the outset, it is crucial to emphasize that we are not suggesting that the price of BTC should be determined by its marginal cost of production. To do so would be to adopt a labor theory of value, which is ostensibly false. Instead, the marginal cost of production is a tool that can help investors estimate a lower bound price level for BTC and other crypto-commodities. 

In 2019, Charles Edwards proposed a methodology to estimate the global average US dollar cost of producing one BTC. The first component of the method is the Cambridge Bitcoin Electricity Consumption Index (CBECI), which provides an up-to-date estimate of the Bitcoin network’s daily electricity load. Edwards estimates the cost of production per BTC by: 

1. Calculating the number of BTC Mined Per Day (based on miner rewards) 
2. Calculating the daily electricity cost to mine one BTC (Daily Electrical Cost) 
3. Estimating the global average “Elec-to-Total Cost Ratio” = (Bitcoin Electrical Cost) / (Daily Cost of running a Bitcoin Mining Business) 

An investor can then compute Bitcoin Production Cost as (Daily Electrical Cost) / (Elec-to-Total Cost Ratio). Finally, the Bitcoin Production Cost is compared to the “Bitcoin Miner Price,” which attempts to capture the revenue one BTC provides to miners. Bitcoin Miner Price is calculated as follows: BTC Price + (Daily Transaction Fees) / (Daily BTC mined). When the BTC price is below the total cost of mining one BTC, it signals that Bitcoin miners may be struggling and potentially taking short-term losses. 

Figure 3: Bitcoin Mining Cost of Production 

Source: 21Shares. Data as of December 31, 2024.

As of December 31, 2024, the estimated global average electricity cost to mine one BTC is $53,240, while the estimated global average total cost to mine one BTC is $88,733. To reiterate, investors shouldn’t interpret this range as the fundamental value of Bitcoin, which is subjective, but rather as an estimate of its price floor based on miner profitability and subsequent behavior patterns. 

Relative valuation

A significant portion of equity valuations in traditional finance consists of relative valuations based upon market sizing and multiples, such as price-to-earnings (P/E ratio). This approach helps determine whether a given asset is undervalued or overvalued relative to its peers and is more likely to reflect market perceptions and sentiment than a fundamental valuation. Moreover, investors can use relative valuations to "price" any asset, not just ones that generate cash flows.

Bitcoin

Investors cannot value store-of-value assets intrinsically because their value is primarily determined by the subjective beliefs of many individuals. Thus, we can utilize a simple market sizing approach to estimate a target price. The methodology involves establishing a Total Addressable Market (TAM) and a percent share the asset in question could take — Market Penetration. For instance, an investor could price Bitcoin by setting a proportion it could capture of the market value of gold, the seminal store-of-value asset. 

As of December 31, 2024, the price of BTC is $93,508, with an implied circulating market cap of approximately $1.83 trillion. On the other hand, the market cap of gold sits at around $17.85 trillion. Thus, we can use the market sizing methodology described above to estimate the hypothetical price of BTC if it were to capture a given percent share of gold’s market cap. For instance, Figure 4 shows that if BTC were to capture 15%, it would be priced at $132,429. In the most optimistic scenario contemplated, if BTC penetrates 30% of gold’s market cap, the price of one BTC would be $264,859. 

Figure 4: Hypothetical Value of BTC as a % of Gold’s Market Cap in 2027

Source: 21Shares. Data as of December 31, 2024.

Challenges to Cryptoasset Valuations

There are various challenges and shortcomings regarding cryptoasset valuations, such as insufficient historical data and complexities unique to the asset class. Valuation models are adapted from traditional finance and may not fully capture the distinct features of cryptoassets, leading to potential inaccuracies particularly in the context of a rapidly changing industry.

For instance, the cash flows that PoS networks generate are not paid in fiat currency but rather in the native tokens of the network. This situation is as if Apple charged its customers in Apple shares instead of U.S. dollars. This unique feature creates a reflexivity problem because the dollar-denominated value of the revenue stream is directly dependent on the crypto asset's value.

We have provided investors with actionable methods to value cryptoassets. The complexity and uncertainty of valuing this asset class might intimidate investors. However, it is worth remembering that the more uncomfortable an investor feels when valuing an asset, the greater the payoff of doing the valuation. Investors are encouraged to use these frameworks as starting points but should run their own models with tailored assumptions to arrive at valuations that align with their individual objectives, and risk tolerance.

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